An operation tool as a gripping device includes a first arm and a second arm that move in directions opposite to each other, and a third arm for engaging with a workpiece. The operation tool includes a gear and a gear moving cylinder for causing the gear to move to a first position, a second position, and a third position between the first position and the second position. The first arm and the second arm move when the gear is disposed at the first position. The third arm moves when the gear is disposed at the second position. The gear is separated from all of the arms when the gear is disposed at the third position.

A gripper for a picking device for small piece goods is provided. The gripper includes a delivery table extending in a first horizontal direction and a second horizontal direction orthogonal to the first horizontal direction, a gripping jaw guide assembly having two gripping jaws extending in the first horizontal direction over the delivery table, wherein at least one of the gripping jaws is movable in the second horizontal direction, and a drive unit which is coupled to the gripping jaw guide assembly and configured to move the gripping jaw guide assembly in the first horizontal direction. At least one of the gripping jaws is configured as a suction jaw and has a suction device having a suction surface for suctioning a small piece good, wherein a vacuum can be applied on the suction device using a suction line.

A robotic surgical tool includes a drive housing having a first end, a second end, and a lead screw extending between the first and second ends, a carriage movably mounted to the lead screw, and an activating mechanism coupled to the carriage. The activating mechanism includes a motor mounted to the carriage and operable to rotate a drive gear, and a driven gear engageable with the drive gear such that rotation of the drive gear causes the driven gear to rotate and thereby actuate the activating mechanism.

The present invention relates to a gripping device for picking up, conveying, and delivering a product, the gripping device including: a base structure which may be attached to a handling device by means of a coupling element, preferably so in a non-destructively detachable manner; at least two gripper members having each at least one bottom surface and at least one top surface, said top surface of the gripper members facing towards the coupling element and said bottom surfaces of the gripper members facing away from the coupling element; at least one drive means for reversibly moving the gripper members between a first position, in which the gripper members may be positioned on opposite sides of the product to be picked up, and a second position, in which the gripper members seize the product to be picked up; and an abutment plate which is at least approximately supported by the top surfaces of the gripper members.

A method of (and an associated device for) applying or measuring the force applied to a sample tube is disclosed. The method includes the steps of driving a plurality of gripping fingers from an open position to a gripping position against a tube, while measuring the movement of first and second coaxial gears driving the fingers before the fingers grip the tube, stopping the movement of the first coaxial gear when the fingers grip the tube, and allowing and measuring a further limited movement of the second coaxial gear after the fingers grip the tube.

A hand 100 includes a first gripper 2 and a second gripper 5. The second gripper 5 grips a workpiece located on a predetermined axis E. The first gripper 2 includes two first fingers 21 that are opened and closed in a predetermined opening/closing direction. Each of the first fingers 21 includes a first part 22 including a distal end and a second part 23 including a proximal end, and is bent or curved such that the first part 222 moves between an interference position M1 at which an imaginary region X defined by projecting the first part 22 in the opening/closing direction A interferes with the axis E and a non-interference position M2 at which the imaginary region X does not interfere with the axis E.

The present disclosure relates to a gripping apparatus for controllably placing an object, the gripping apparatus including: a gripper assembly mounted to a robot arm via a connector body, the gripper assembly including a housing that supports one or more gripper drive assemblies operatively coupled to a pair of opposing gripping clamps, and in use the robot arm is configured to drive the gripper assembly along a placement axis towards a placement surface via the connector body; a sensor configured to either measure a relative movement between the gripper assembly and the connector body or to measure a force between the gripper assembly and the connector body, wherein the sensor generates a sensor output signal based on the measurement; and, a controller configured to send a stop signal to the robot arm to stop further drive of the gripper assembly along the placement axis when the sensor output signal indicates the measured relative movement or measured force exceeds a predefined threshold.

A robotic gripping device includes a base part attached to a tip of a wrist of a robot; finger parts, at least one of which is movably supported on the base part so that the finger parts can move toward and away from each other; and a driving mechanism that drives the finger parts. In at least one of the finger parts, flexibility of at least a gripping surface is switchable.

A gripper apparatus including a gripper frame and a gripper beak; an actuation mechanism for actuating the gripper beak; a clamping force generator biased to exert a clamping force on the gripper beak; a transmission mechanism including an input member that is vertically displaceable with respect to the gripper frame, wherein the transmission mechanism engages the actuation mechanism such that a high position of the input member corresponds to a closed position of the gripper beak while a downward displacement of the input member corresponds to a transition of the gripper beak to an open position; a vertically displaceable carrier coupling device that in a lower rest position presses down on the input member; and a latch mechanism, preferably of alternate push-push type, for holding the gripper beak in its open position.

A method of (and an associated device for) applying or measuring the force applied to a sample tube is disclosed. The method includes the steps of driving a plurality of gripping fingers from an open position to a gripping position against a tube, while measuring the movement of first and second coaxial gears driving the fingers before the fingers grip the tube, stopping the movement of the first coaxial gear when the fingers grip the tube, and allowing and measuring a further limited movement of the second coaxial gear after the fingers grip the tube.